Observation of partonic collectivity via p T-differential radial flow fluctuations in Au+Au collisions at s NN = 200 GeV
Abstract
We report the observation of partonic radial collectivity in Au+Au collisions at s NN = 200~GeV via the p T-differential flow observable v0(p T) using the AMPT String Melting model. For inclusive charged hadrons, we establish three signatures of collectivity: long-range pseudorapidity correlations, the factorization of two-particle correlations, and a centrality-independent scaling of v0(p T) normalized by its p T-integrated value v0, analogous to anisotropic flow. For identified particles (π, K, p + p), the v0(p T) spectra show mass ordering at low-p T and meson-baryon separation at intermediate-p T. In central collisions, v0(p T)/nq exhibits robust Number of Constituent Quark (NCQ) scaling with (m T - m0)/nq, a scaling that breaks down in peripheral collisions and is more precise at RHIC than at LHC energies, consistent with earlier v2 studies. These findings provide strong evidence that radial collectivity originates predominantly at the partonic stage, extending the paradigm of quark-level dynamics from anisotropic to isotropic flow.
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